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how to check whether a number is divisible by 5 or not without using % and / operator. I want a quickest algorithm for this problem.

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4  
Great! Why do you need to do this? What have you tried so far? –  Oliver Charlesworth Jun 14 '13 at 17:00
    
Cast number into a string, extract last “character” and see whether it’s a 0 or 5 – or something else …? –  CBroe Jun 14 '13 at 17:00
    
@Oli Charlesworth -subtracting 5 with the number until i get 0 or negative number. 0 means divisible by 5,negative means not divisible by 5.but for a big number it will take too much time. –  Kushagra Jaiswal Jun 14 '13 at 17:02
5  
@user2484070: There is no mechanism that is going to be as fast as simply doing %. So I would suggest using %! –  Oliver Charlesworth Jun 14 '13 at 17:05
1  
+1 The questing is not clear, and probably the OP wants someone to do their homework, but we had some good answer that may be very helpful for people that have this as a real issue. –  Jonatan Goebel Jun 14 '13 at 17:37

8 Answers 8

up vote 11 down vote accepted

A good starting point is to look into how division can be accomplished with multiplication and bit-shifts. This question is one place to look.

In particular, you can follow the attached post to hit upon the following strategy. First, "divide by 5" using multiplication and bit-shifts:

 int32_t div5(int32_t dividend) {
     int64_t invDivisor = 0x33333333;
     return 1 + (int32_t) ((invDivisor * dividend) >> 32);
 }

Then, take the result and multiply by 5:

int result = div5(dividend) * 5;

Then, result == dividend if and only dividend is divisible by 5.

if(result == dividend) {
    // dividend is divisible by 5
}
else {
    // dividend is not divisible by 5
}
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@Jason Thank you for the helpful edit! –  1'' Jun 14 '13 at 17:43
    
You have to run this in a loop if say, the dividend is 5^5 right? I guess that's still a pretty good runtime. –  roliu Jun 14 '13 at 17:44
    
@roliu: No, no loop. The result of div5(3125) will be 625, which multiplied by 5 is 3125 which is equal to the dividend which says 3125 is divisible by 5. Note the result of div5(3125 + 1) will be 625 but multiplied by 5 gives 3125 which is not 3125 + 1 which says 3125 + 1 is not divisible by 5. –  Jason Jun 14 '13 at 17:47
1  
This formula gives an approximation, int fact, it will return num/5 - 1. So you need a + 1 in the return statement. This is valid only for the special case where the divisor is 5. –  Jonatan Goebel Jun 14 '13 at 17:57
1  
@jason -good stuff !! thank u :) –  Kushagra Jaiswal Jun 14 '13 at 18:10

There are two reasons I can see for wanting such an algorithm: (1) homework, or (2) writing efficient code for a microcontroller which does not have efficient division instructions. Assuming your reason is the second, but allowing for the possibility that it might be the first, I won't give you a full solution, but will suggest that if you divide your number into chunks that are a multiple of four bits each, the sum of all those chunks will be divisible by five only if the original number was; note that when performing such computation you must either avoid overflows or else add to your result the number of overflows that have occurred. I don't know any efficient way to do the latter in C, but in many machine languages it is easy. As a simple example, on the 8051 if one had a 32-bit integer, one could so something like:

    mov a,Number   ; Byte 0
    add a,Number+1 ; Byte 1
    adc a,Number+2 ; Byte 2, plus carry from last add
    adc a,Number+3 ; Byte 3, plus carry from last add
    adc a,#0       ; Add in carry, if any (might overflow)
    adc a,#0       ; Add in carry, if any (can't overflow)

Note that in the machine code, adding the carries back into the number is much faster than performing 16-bit math would be.

Once the value has been reduced to the range 0-255, one could add the upper four bits to the lower 4 bits to get a value in the range 0 to 30. One could either test for the seven such values that are multiples of five, or work to reduce the number of possible values further [e.g. if the value is at least 15, subtract 15; if at least 10, subtract 10; if 5, subtract five; if zero, it's a multiple of five].

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How does one show that this always works? –  Oliver Charlesworth Jun 14 '13 at 17:24
    
@OliCharlesworth: What is the value of (16%5)? What is the value of (16%5) squared? Cubed? Raised to the 492nd power? What is the value of 255%5? Making a carry add one to a value instead of 256 will cause the value to be 255 less after each overflow than it would be if the carry added 256. What's the value of 255%5? –  supercat Jun 14 '13 at 17:33
    
Aha, yes, that makes sense. (a+16)%5 == (a+1)%5. Good stuff! –  Oliver Charlesworth Jun 14 '13 at 17:35

Let's represent the number in base 2. We have:

abcdefgh*101 = ABCDEFGHIJ

or

+abcdefgh00
+  abcdefgh
 ----------
 ABCDEFGHIJ

We are given ABCDEFGHIJ and want to find abcdefgh.

If you alternately - and + ABCDEFGH with its successive rightshift-by-2, you will get...

+  ABCDEFGH
-    ABCDEF
+      ABCD
-        AB
-----------
+  abcdefgh
+    abcdef
-    abcdef
-      abcd
+      abcd
+        ab
-        ab
-----------
   abcdefgh

The answer!

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When you have the division result you can multiply it back with 5 to check the remainder –  Lưu Vĩnh Phúc Aug 2 '13 at 14:54
bool trythis(int number){
  Int start = number;
  Do{
    start = start - 5;
  } while (start > 5)

  If (start == 5 || start == 0) {
    Return true;
  } else return false;
}
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It finally got unlocked, so I can explain my comment, which incidentally turns out to generate better code than GCC does for x % 5 == 0. See here, fill in

#include <stdint.h>
bool divisible_by_5(uint32_t x)
{
   return x % 5 == 0;
}
bool divisible_by_5_fast(uint32_t x)
{
   return x * 0xCCCCCCCD <= 0x33333333;
}

I'll assume unsigned input, because the OP suggested an algorithm that only works with positive input. This method can be extended to signed input, but it's a little messy.

0xCCCCCCCD is the modular multiplicative inverse of 5, modulo 232. Multiplying a multiple of k (for example, n * k) by the (modular) multiplicative inverse is equivalent to dividing by k, because

(n * k) * inv(k) =
// use associativity
n * (k * inv(k)) =
// use definition of multiplicative inverse
n * 1 =
// multiplicative identity
n

Modulo powers of two, a number has a modular multiplicative inverse iff it is odd.

Since multiplying by an odd number is invertible and is actually a bijection, it can't map any non-multiples of k to the 0 - (232-1)/k range.

So when it's outside that range, it can't have been a multiple of k.

0x33333333 is (232-1)/5, so if x * 0xCCCCCCCD higher, x can't have been a multiple of 5.

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Keep subtracting by multiples of 5 like 50, 500,100, etc. Start with big numbers. If the result goes in negative then subtract with a smaller number number until you reach 0. Otherwise the number is not divisible.

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Add all the bytes and check (by table look-up) if the sum is divisible by 5.

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1  
Actually that works, because 256 % 5 = 1, and therefore the "multiplier" for each digit is 1 (ie, just add them). If it hadn't been 1, the algorithm with a digital sum still works, but you'd have to scale every digit by some amount. –  harold Jun 14 '13 at 20:27
    
@harold was thinking bits. Would be really happy to +1 this if Egor edits it (-1 locked). –  Ziyao Wei Jun 14 '13 at 23:35

Typecast or convert to a string, then see if the final character is a 5 or 0.

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5  
This will use (implicitely) the / and/or % operators.. –  xtof pernod Jun 14 '13 at 17:06

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